DE19528835A1 - Prodn. of required contour of workpiece for mfg. injection moulding dies - with measurement and comparison of the actual and required contours, and removal of a masking coating from places where subsequent contour deepening or heightening is required - Google Patents

Abstract

Prodn. of a required contour of a workpiece (3), is claimed. The actual contour of at least of a part of the workpiece is measured and compared with the required contour. The workpiece is provided with an etchant resisting coating (7). This coating is removed in places (8) where the required contour is deeper than the actual contour, and workpiece material is removed by etching from these places.

Description

The invention relates to a method for producing a Target contour of a workpiece having an actual contour, especially an injection mold.

A method for producing a target contour is already known, where the contour of the workpiece is first pre-milled For example, roughly to the desired one with a multi-cutter Target contour is approximated. The pre-milling is done so that the actual contour of the workpiece is slightly larger after the pre-milling process is as the desired target contour, thus from the actual contour then produced in the target contour by finish milling can be. Although through this gradual editing of the Workpiece a comparatively high for machining Surface quality can be achieved, so milling grooves can nevertheless cannot be completely avoided. Also prepares the manufacture complicated and in particular finely structured target contours, the places that are not or only poorly with the milling cutter difficulties are still attainable. Another disadvantage of previously known method is that finishing milling, which is usually carried out in several work steps, is comparatively time-consuming. Target contours with large  Surface such as that used for injection molding tools Manufacture of larger plastic parts can occur can only be produced with the appropriate time and cost.

A method of the type mentioned at the outset is also known, in which the target contour by pump erosive lowering from the Actual contour is produced. With this method, the workpiece is together with a tool electrode having the target contour arranged in a dielectric. Between the tool electrode and the workpiece are sparked by electrical impulses strikes generated by the workpiece by melting, evaporation and / or electrical forces each have small amounts of material remove. During the removal process, the tool electrode by gravity and / or a suitable feed device lowered into the workpiece. The known method is comparatively complex and is mainly suitable for Manufacture of small workpieces. The production of workpieces with large, three-dimensional curved surfaces is with this However, proceedings are not possible or only very poorly.

A method is also already known in which the target contour of the Workpiece by removing workpiece material using a laser radiation is produced from the actual contour. As for the Laser material processing a comparatively high beam power, for example, 1 kW is required, the method and the machines required for its implementation are relatively expensive. In addition, the working speeds are comparatively low achievable, so that the production of large target contours with a is associated with a correspondingly high expenditure of time. Besides, they are Surface quality and the dimensional accuracy of one with this Process contour produced only comparatively low.

There is therefore the task of a process of the beginning to create the type mentioned, with the workpiece target contours large surface with better dimensional accuracy  are producible.

The solution to this problem is that the actual office at least a portion of the workpiece is measured that the actual contour is compared with the target contour that on the Workpiece is applied an etch-resistant coating that the coating at the processing points where the Target contour of the workpiece is deepened compared to the actual contour, is removed and that subsequently works in these places piece material is removed by etching.

In the method according to the invention, therefore, the workpiece an etch-resistant coating, which is then applied at the points where the actual contour is larger than the target contour or at which the actual contour is in the target contour protrudes, is removed again. The surface of the workpiece is then in the places where the production of the Target contour still has to be removed, free accessible while the remaining areas of the workpiece surface are covered by a caustic mask. With the masked like this The workpiece can have the desired contour by etching the workpiece be made in a simple manner. Because by etching the whole Surface of the workpiece can be processed simultaneously, the method according to the invention is particularly suitable for inexpensive manufacture of large, three-dimensional workpiece geometries. Acid-resistant are preferably used as the coating material Varnishes for use. The layer thickness depends on the paint system and etching medium already sufficient a few micrometers. Since that Coating material compared to the material material can be removed much easier and faster the method according to the invention in particular in difficult to access Workpiece locations, such as inside of injection molding men, a significant reduction in manufacturing costs for the Target contour. By comparing the actual and target contour, this can be done Workpiece also with high dimensional and surface accuracy  getting produced.

In a particularly advantageous embodiment of the invention it is provided that the actual contour of the workpiece after a measure the previous etching process again and with the specified one Target contour is compared that at least on the workpiece the previously processed places again an etch-resistant Coating is applied that the coating on the Machining points at which the target contour of the workpiece is deepened compared to the actual contour, is removed and that then workpiece material at these points by etching is removed. The method according to the invention can also be applied in several stages, with the workpiece in front of each The etching process is measured again and masked. This allows even complicated three-dimensional workpiece geometries such as these for example in an injection mold for the manufacture of Plastic dashboards with a textured leather surface are required, manufactured with high surface accuracy will. The method is also particularly suitable for production complicated free-form surfaces on artificial hip joints Stainless steel or titanium.

The above object can be achieved in a method of mentioned type can also be solved in that the Measure the actual contour of at least a portion of a workpiece is that the actual contour is compared with the target contour that an electrically non-conductive coating on the workpiece applied that the coating at the processing points, on which the actual contour of the workpiece compared to the target contour is deepened, is removed and that subsequently at these points Material is electroplated. So with this procedure an electrically insulating coating on the workpiece then applied at the points where the Actual contour is smaller than the target contour or at which the target contour protrudes outward beyond the actual contour  Will get removed. The workpiece surface is thus masked that only the areas of the workpiece surface are exposed, on which still workpiece material for the production of the target contour must be applied. Through the subsequent galvanization process, the target contour can therefore be produced in a simple manner will. Since the entire surface of the Workpiece adjusted or approximated to the target contour at the same time the method according to the invention is particularly suitable for the production of three-dimensional geometries with large Surfaces. As with the method of claim 1 enables the actual contour to be measured and compared with the target contour a high dimensional and surface accuracy.

In a preferred embodiment of the method provided that the actual contour of the workpiece after previous Measure the galvanization again and with the specified target contour it is compared that on the workpiece at least to the previously processing points again an electrically non-conductive Coating is applied that the coating on the Machining points at which the actual contour of the workpiece is deepened relative to the target contour, is removed and that material is then electroplated at these points. The The method can thus also be the method according to claim 1 is applied in several stages, so that in particular complicated, three-dimensional geometries can be produced even more precisely.

A further development of the invention, for independent protection coveted, provides that the coating by means of laser radiation is preferably removed by direct writing. With the laser beam, the coating can be made contactless with high Processing speed can be masked. By modulation of the laser beam can also be used at feed speeds resolutions of up to several hundred meters per minute can be achieved in the micrometer range. Since the thickness of one ins special coating designed as a lacquer layer only a few  µm can be and their evaporation energy compared to the workpiece material, for example a metal, is very low is for removing the coating compared to the direct removal of the workpiece material using a laser only Fractions of time and laser power required. Compared to processes in which the workpiece material is directly laser can be removed with a much smaller and less expensive laser, for example a laser up to 100 watts Beam power to be worked. Because the removal of the work piece material by means of the etchant and / or electroplating of the workpiece material at all exposed positions at the same time the desired surface geometry is quickly achieved.

In another embodiment of the invention is as Coating uses a photosensitive varnish, this one Paint exposed at the processing points with laser radiation and then removed at these locations with a developer. The masking of the coating can then be done with an even smaller one Laser power take place, so that a correspondingly small and inexpensive laser can be used. By modulation the laser radiation can also in this embodiment Invention at very high feed speeds still resolutions can be achieved in the micrometer range. The desired target contour can therefore be inexpensive and especially for large workpieces be manufactured with high dimensional accuracy.

A preferred embodiment of the method provides that the coating is only applied after measuring the actual contour becomes. The measurement result is then not due to the coating influences what a particularly exact measurement of the actual contour enables.

In another embodiment of the method, that the coating already before measuring the actual contour is applied and that the thickness of the coating, if necessary  when comparing the actual and target contour by subtracting from the actual contour or by adding it to the target contour becomes. The actual contour can then also during the removal of the Coating can be measured from the processing points so that the measurement of the actual contour, its comparison with the target contour and removing the coating practically in one operation can be carried out. The processing time can thereby can also be reduced. So that the coating better the comparison of the actual and target contour can be taken into account, it is advantageous if the coating with defined and layer thickness applied to the workpiece as constant as possible becomes.

In a particularly inexpensive process variant, this is Measure the workpiece with a touching sensor. Can as a sensor then an inexpensive tactile sensor, for example a stylus, are used.

It is particularly advantageous if the actual contour of the workpiece is measured optically. The measurement is then carried out without contact, causing mechanical damage to the coating avoided and on the other hand also particularly high scans speeds are made possible.

This enables a particularly exact determination of the actual contour achieved that the workpiece is measured with laser radiation becomes. For example, interference measurement methods for Applications that enable resolutions in the nanometer range. In addition, the measuring laser radiation through narrow-band optical Filters particularly good against optical interference, such as wise scattered or extraneous light, are shielded.

In an expedient embodiment of the method provided that the workpiece for applying the coating in a coating bath is immersed. The coating can therefore particularly well in places that are difficult to access, for example, in corner areas of the workpiece.  

Another embodiment of the method provides that the Coating is applied to the workpiece by spraying. The coating material can be particularly uniform and are applied with a defined layer thickness, in particular the realization of thin layers is also possible.

The actual contour of the workpiece can also be removed during removal of the coating can be measured by the processing points. This can be done, for example, with a coaxial to the machining laser beam measuring optical distance from the processing point Sensor can be used, the measurement value determination directly the processing point enables. The actual contour determined in this way can then directly with a control computer with the target contour compared and for example for positioning the workpiece relative to a machining laser beam.

Of course, for an online measurement of the actual contour during the removal of the coating also a before Sensor can be used. The comparison values between actual and The target position must then take into account the sensor advance delayed for controlling the machining tool (e.g. the Laser beam) can be used.

Below are exemplary embodiments of the invention based on the Drawing explained in more detail.

Some show more schematically:

Fig. 1 is a partial cross-section through which the actual contour having uncoated workpiece, and the optical sensor for measuring the actual contour is visible,

Fig. 2 is a partial cross-sectional contour of the workpiece after application of an etch resistant coating on the target,

Fig. 3 is a partial cross section through the assembly shown in Fig. 2 workpiece during the masking of the coating by means of laser radiation

Fig. 4, the workpiece shown in Fig. 3 after the etching away of the workpiece material at the non-covered by the coating workpiece areas,

Fig. 5 is a partial cross-section through which the desired contour on-setting, finished workpiece after complete removal of the etch-resistant coating,

Fig. 6 is a schematic representation of a laser material processing station for removing the coating, the focusing optics for the laser radiation to illustrate the beam path and that of the coaxial optical radiation of the actual contour sensor is shown in section, and

FIG. 7 shows a representation similar to FIG. 6, but, in contrast to FIG. 6, the focusing lens for the laser radiation is arranged outside the beam path of the optical sensor.

In a method for producing a target contour 1 of a workpiece having an actual contour 2 , the actual contour 2 of at least a partial area of the workpiece 3 is measured. After or during the measurement, the actual contour 2 is compared with the target contour 1 . For this purpose, the target contour 1 is stored in numerical form in the memory 4 of a measuring and control computer 5 , which has a comparison unit 6 for forming the difference between the actual contour 2 and the target contour 1 .

After measuring the actual contour, an etch-resistant coating 7 is applied to the workpiece 3 in the partial area of the workpiece 3 which has the actual contour ( FIG. 2). Varnishes, photopolymers, caustic metals or other caustic materials can be used as coating material. Subsequently, the coating 7 at the processing points 8 , at which the comparison of the target contour 1 and the actual contour 2 has shown that the target contour 1 is deepened relative to the actual contour 2, is removed by means of laser radiation 9 using the direct writing method.

The laser radiation 9 is guided by the resonator of a laser 10 with a suitable beam guidance system to a focusing optics 11 , which places the laser radiation 9 on the processing 8 ( FIGS. 6 and 7). The energy density in the focus is such that when the laser beam 9 strikes the processing point 8 , the coating 7 is removed by thermal heating, but the workpiece 3 underneath is not damaged by the laser beam 9 . For this purpose, the laser 10 typically has a beam power of up to 100 watts.

The focusing optics 11 can be moved in multiple axes relative to the workpiece 3 with a positioning device controlled by the measuring and control computer 5 . To mask the coating 7 , the focus of the focusing optics 11 , controlled by the measuring and control computer 5 , is moved in a line-like manner along the actual contour, the individual lines for scanning the actual contour 2 being arranged closely adjacent to one another. The laser radiation 9 is modulated so that it only strikes the coating 7 to a significant extent at the processing points 8 . The laser radiation 9 is thus blanked between the processing points 8 . The modulation of the laser radiation 9 is synchronized by the measuring and control computer 5 to the spatial arrangement of the processing points 8 .

After the coating 7 has been removed from the processing points 8 , the workpiece 3 is immersed in an etchant for a defined period of time. Workpiece material is removed by etching at the processing points 8 , while the remaining areas covered by the etch-resistant coating 7 are not changed by the etchant ( FIG. 4). Workpiece material is thus removed by the etchant precisely at those points at which the actual contour 2 projects into the target contour 1 . The actual contour 2 is thus approximated to the target contour 1 by the etching process until it almost completely corresponds to the latter. The workpiece 3 is then removed from the etching bath, cleaned of etchant residues and then the coating 7 still remaining on the workpiece surface is removed ( FIG. 5). This can be done either by means of laser material processing or with another method that has to be carried out depending on the geometry of the workpiece 3 .

The method according to the invention can also be carried out with multi-stage etching be carried out, depending on the task, the workpiece surface possibly re-measured and, if necessary, also coated and to be masked. It should also be mentioned that the The inventive method can also be used Milling grooves that lead to deviations of the actual from the target geometry can result in removal.

The actual contour 2 can also be measured while the coating is being removed from the processing points 8 . In the exemplary embodiment according to FIGS. 6 and 7, the focusing optics 11 have an optical sensor 12 which, in order to measure the distance between the focusing optics 11 and the processing point 8, emits an optical measuring beam 13 in the direction of the processing point during processing, the longitudinal axis of which is coaxial with the central axis the laser radiation 9 incident on the workpiece 3 is arranged.

The measuring beam 13 is coupled into the laser radiation 9 by means of a deflection mirror 14 , which deflects the laser radiation 9 arriving from the laser 10 onto the workpiece 3 by 90 °. The optical sensor 12 is arranged behind the deflecting mirror 14, so in the range whose Spie facing away from the reflector side gelrückseite 15 and the optical probe beam 13 passes through an opening 16 in the deflection mirror fourteenth The deflection mirror 14 can also consist of a material which is permeable to the optical measuring beam 13 . In this case, the opening 16 can be omitted.

In the embodiment according to FIG. 6, both the measuring beam 13 and the laser radiation through a common focusing lens 9 17 are guided, which is arranged between the mirror 14 and the machining point 8. However, a separate focusing device 18 can also be provided for the measuring beam 13 . In this case, the focusing lens 17 for the laser radiation 9 is arranged between the deflecting mirror 14 and the laser 10 .

Claims (15)

1. Method for producing a target contour of a workpiece having an actual contour, in particular an injection mold, characterized in that the actual contour of at least a partial area of the workpiece is measured, that the actual contour is compared with the target contour, that an etch-resistant coating is applied to the workpiece, that the coating is removed at the machining points where the target contour of the workpiece is deepened compared to the actual contour, and that workpiece material is subsequently removed by etching at these points. 2. The method according to claim 1, characterized in that the Actual contour of the workpiece after a previous etching process measured again and with the specified target contour it is compared that on the workpiece at least to the previously treated areas again with an etch-resistant coating is applied that the coating on the machining put against which the target contour of the workpiece the actual contour is deepened, removed and that subsequently workpiece material is removed by etching at these points becomes. 3. The method according to the preamble of claim 1, characterized characterized in that the actual contour of at least a portion of the workpiece is measured that the actual contour with the Target contour is compared that a on the workpiece electrically non-conductive coating is applied that the coating at the processing points where the The actual contour of the workpiece is deepened compared to the target contour is removed and that subsequently at these points Material is electroplated. 4. The method according to claim 3, characterized in that the  Actual contour of the workpiece after a previous electroplating Measurement process again and with the specified Target contour is compared that at least on the workpiece at the previously processed places again an electrical non-conductive coating is applied that the Coating at the processing points where the The actual contour of the workpiece is deepened compared to the target contour is removed and that subsequently material at these points is electroplated. 5. The method according to any one of claims 1 to 4, characterized characterized in that the coating by means of laser radiation is preferably removed by direct writing. 6. The method according to any one of claims 1 to 5, characterized characterized in that a photosensitive coating Varnish is used to work on this varnish exposed to laser radiation and then on these spots are removed with a developer. 7. The method according to any one of claims 1 to 6, characterized characterized in that the coating only after the Measuring the actual contour is applied. 8. The method according to any one of claims 1 to 7, characterized characterized in that the coating before the measurement the actual contour is applied and that the thickness of the Coating if necessary when comparing actual and Target contour by subtracting from the actual contour or by Adding to the target contour is taken into account. 9. The method according to any one of claims 1 to 8, characterized characterized in that the actual contour of the workpiece with a touching sensor is measured.   10. The method according to any one of claims 1 to 9, characterized characterized in that the actual contour of the workpiece with an ultrasonic sensor is measured. 11. The method according to any one of claims 1 to 10, characterized characterized in that the actual contour of the workpiece is optical is measured. 12. The method according to any one of claims 1 to 11, characterized characterized in that the actual contour of the workpiece with Laser radiation is measured. 13. The method according to any one of claims 1 to 12, characterized characterized in that the workpiece for applying the Coating is immersed in a coating bath. 14. The method according to any one of claims 1 to 13, characterized characterized in that the coating by spraying on the Workpiece is applied. 15. The method according to any one of claims 1 to 14, characterized characterized in that the actual contour during the removal of the Coating is measured by the processing points.